A novel coronavirus emerged in human populations and spread rapidly to cause the global coronavirus disease 2019 pandemic. Although the origin of the associated virus (severe acute respiratory syndrome coronavirus 2 [SARS-CoV-2]) remains unclear, genetic evidence suggests that bats are a reservoir host of the virus, and pangolins are a probable intermediate. SARS-CoV-2 has crossed the species barrier to infect humans and other animal species, and infected humans can facilitate reverse-zoonotic transmission to animals. Considering the rapidly changing interconnections among people, animals, and ecosystems, traditional roles of veterinarians should evolve to include transdisciplinary roles.

The targeted RNA recombination was attempted to substitute the membrane (M) protein gene and part of the nucleocapsid (N) protein gene of mouse hepatitis virus with the corresponding sequences from bovine coronavirus. Using a defective interfering (DI) RNA-like cDNA construct derived from pMH54, 690 nucleotides representing the entire M gene and the 5' most 915 nucleotides of the N gene of the mouse hepatitis virus Albany 4 mutant were attempted to be replaced. Upon infection of cells with Albany 4 followed by transfection with synthetic RNA transcribed from the DI-like cDNA construct, recombinant mouse hepatitis viruses as the large plaque forming phenotype were isolated by plaque assays at the non-permissive temperature of 391 degrees C. By RT-PCR and sequencing, those large plaque phenotypes were confirmed to have contained the thermostable phenotype marker derived from the transfected RNA, demonstrating that recombination occurred between the Albany 4 genomic RNA and the in vitro RNA transcripts. Further analysis of the recombinant viruses indicated that there combination had taken place within the region of 222 nucleotides between positions 916 and 1,137 of the N gene. This is the region immediately downstream of the replacement sequence and the start of the temperature resistant phenotype marker. The results suggest that the M and part of the N genes of bovine coronavirus may not be able to complement the function of those of mouse hepatitis virus. This study redirects our current approach of utilizing the MHV targeted RNA recombination as a means to study bovine coronavirus genetics towards the construction of an infectious cDNA clone.
Amino Acid Sequence ; Animals ; Base Sequence ; Cattle ; Cells, Cultured ; Coronavirus, Bovine/*genetics ; DNA, Complementary/genetics ; Gene Targeting/veterinary ; Genetic Vectors ; Mice ; Molecular Sequence Data ; Murine hepatitis virus/*genetics ; Nucleocapsid Proteins/*genetics ; Phenotype ; Plaque Assay/veterinary ; RNA, Viral/chemistry/*genetics/isolation&purification ; Reverse Transcriptase Polymerase Chain Reaction/methods/veterinary ; Sequence Homology, Amino Acid ; Transfection/veterinary ; Viral Matrix Proteins/*genetics

African swine fever (ASF), caused by the ASF virus, a member of the Asfarviridae family, is one of the most important diseases in the swine industry due to its clinical and economic impacts. Since the first report of ASF a century ago, ample information has become available, but prevention and treatment measures are still inadequate. Two waves of epizootic outbreaks have occurred worldwide. While the first wave of the epizootic outbreak was controlled in most of the infected areas, the second wave is currently active in the European and Asian continents, causing severe economic losses to the pig industry. There are different patterns of spreading in the outbreaks between those in European and Asian countries. Prevention and control of ASF are very difficult due to the lack of available vaccines and effective therapeutic measures. However, recent outbreaks in South Korea have been successfully controlled on swine farms, although feral pigs are periodically being found to be positive for the ASF virus. Therefore, we would like to share our story regarding the preparation and application of control measures. The success in controlling ASF on farms in South Korea is largely due to the awareness and education of swine farmers and practitioners, the early detection of infected animals, the implementation of strict control policies by the government, and widespread sharing of information among stakeholders. Based on the experience gained from the outbreaks in South Korea, this review describes the current understanding of the ASF virus and its pathogenic mechanisms, epidemiology, and control.